Syntheses of novel catalytic polyelectrolytes from poly (N-(2, 4

2882

Syntheses of Novel Catalytic Polyelectrolytes from Poly( N - (2,4-dinitrophenyl)-4-vinylpyridinium chloride) and Amines or Amino Acids and Their Rate-Enhancing Effects in Ester Hydrolyses' Norio h e , * Tsuneo Okubo, Hiromi Kitano, and Shigeru Kunugi Contribution from the Department of Polymer Chemistry, Kyoto University, Kyoto, Japan. Received September 30, 1974

Abstract: Polymers catalyzing the hydrolysis of nitrophenyl esters were studied using polyelectrolytes (11) synthesized by

reacting poly(N-(2,4-dinitrophenyl)-4-vinylpyridiniumchloride) (I) with histamine or histamine mixed with other amino derivatives. I was obtained by quaternization of poly(4-vinylpyridine) [or poly(4-vinylpyridine) partially quaternized with alkyl halide] with 2,4-dinitrochlorobenzene.The kinetics 'of the reactions of I with amines or amino acids were investigated in water and 2.5% ethanol-water at 2 5 O using the rapid-scan stopped-flow technique. The formation of I1 was characterized by two relaxation times, namely an amine-independent fast process (40-50 sec-I) and an amine-dependent slow process (4-9 X sec-I). I1 was prepared by reacting I with histamine or histamine mixed with n-butylamine, n-cetylamine, P-hydroxyethylamine, and/or P-carboxyethylamine. The hydrolyses of neutral and anionic esters, i.e., p-nitrophenyl acetate, p-nitrophenyl propionate, and 3-nitro-4-acetoxybenzoicacid with the polyelectrolytes (11) above obtained followed saturation kinetics in alkaline regions. The catalyses by the polyelectrolytes (11) were discussed in terms of the two contributions, Le., (1) catalysis by imidazolyl group and (2) electrostatic catalysis for the alkaline hydrolysis. It was demonstrated that the polyelectrolytes catalyzed the ester hydrolysis largely by the first factor.

Recently, a variety of esterolytic catalyses by polymers containing imidazole groups or other nucleophiles have been investigated as cu-chymotrypsin In common with almost all enzymes, the reactions catalyzed by achymotrypsin a r e characterized by a saturation phenomenon, which implies that the enzyme binds the substrate before the catalytic reaction occurs. Attempts, therefore, have been m a d e to construct synthetic polymers by introducing binding groups besides catalytic sites. In the present paper, we report novel catalytic polyelectrolytes (11) prepared from poly(4-vinylpyridine) partially quaternized with 2,4-dinitrochlorobenzenewhich can react with a variety of amino derivatives R N H 2 a t room temperature in water or other polar solvent (methanol, ethanol, dimethylformamide, etc.) to yield 2,4-dinitroaniline and polyvinylpyridine quaternized with R group. In 1904, ZinckeI5 and Konig16 reported independently that N - (2,4-dinitropheny1)pyridinium ions reacted with amines to give a reddish adduct, and detailed studies of this reaction were reported later. i','* Our polymer preparation was analogous to these procedures.

MKII) with a recorder (Riken Denshi Co., Ltd, Model SP-H). The precision of the bridge is claimed to be &0.01% according to the manufacturer. Kinetic Measurements. Kinetic measurements of the reaction of I with amine or amino acid were carried out spectrophotometrically by using a Hitachi rapid scan spectrophotometer (Model RSP2 ) equipped with thermostated cell holder and a Union stoppedflow spectrophotometer (Model RAllOO), a product of the Union Engineering, Hirakata, Osaka-fu. The details of the RSP-2 spectrophotometer were described e l s e ~ h e r e . l ~The ~ * ~RA1100 photometer consists of a four-jet mixer and an observation cell with a I-cm optical path length. The dead time of the apparatus was 1.0 msec by the flow-speed measurements. The hydrolyses of esters were followed using a pH-stat potentiometer (Model lo]), a product of the Hiranuma Industry Co., Mito, Ibaraki, by detecting acid released. The initial hydrolysis rate, V O , was determined by a linear extrapolation of the rate within 10% conversion. The rate of hydrolysis by polymer catalyst,*' Vcat, was defined as vcat = vo - vo*, where VO* indicates the rate in the absence of the catalyst. The hydrolyses of all esters studied showed saturation phenomena with respect to the substrate concentration, and the Michaelis-Menten kinetics were applied: hi

c+stlc.s

Experimental Section

+c

(1)

k2

Materials. Poly(4-vinylpyridine) was prepared by bulk polymerization of 4-vinylpyridine with benzoyl peroxide, as described before.I9 The degree of polymerization was 3800. @-Hydroxyethylamine, 1-tryptophan, and histamine were obtained from Fluka AG, and 1-P-phenyl-a-alanine and tyrosine were obtained from Sigma Chemicals Co. The other amines and amino acids were commercially available. 3-Nitro-4-acetoxybenzoic acid (NABA) was prepared by the method of Overberger et aL5 and Kunitake et a1.8 p-Nitrophenyl acetate (PNPA) obtained from Nakarai Chemicals Co., Kyoto, was further purified by recrystallization (mp 78'). p-Nitrophenyl propionate (PNPPR) obtained from Sigma Chemicals Co. was used without further purification. Dimethylformamide and dioxane used were spectral grade reagents. Deionized water distilled using a Yamato auto still (Model WAG-21) and spectroscopic grade ethanol were used for the preparation of the solutions of esters and polymer catalysts. Conductance Measurements. The quaternization of poly(4-vinylpyridine) with 2,4-dinitrochlorobenzenewas followed in an electrolytic cell of the Jones-Ballinger type (cell constant = 7.64 cm-I) using an autobalance precision bridge (Wayne K e n , Model B331

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where C, S, CS, and P denote the catalytic moiety (imidazolyl group) of the polymer catalyst, the substrate, the complex of the catalytic moiety and the substrate, and the hydrolyzed product, respectively. The rate of the hydrolysis is expressed as shown in eq 2 and 3, where K , is the Michaelis-Menten constant, and [C]o and

(3) [SI0 are the initial concentrations of the imidazolyl group and of the substrate.

Results and Discussion Syntheses of Polycations (I). T h e syntheses of the polycation (I) were followed by the time dependence of the specific conductance ( K ) of the reaction mixture, Le., poly(42,4-dinitrochlorobenzene dimethylforvinylpyridine)

/ May 14, 1975

+

+

2883 Table I. Composition of Partially Quaternized Polycations (I) Mole fraction of alkyl Mole fraction of 2,4Code dinitrophenyl groups or benzyl groups 0 0

0.18 0.072 0.23 0.24 0.30 0.53 0.62 0.i2 0.13 0.15

RP3 RP4 RP5 RP7-10 RP7-20 RP7-40 RP7-70 RP8 1 RP9 RPll-3

Mole fraction of unquaternized pyridyl groups 0.82 0.93

Solvent used in quaternization with 2,4-dinitrochlorobenzene Methanol DMFa Nitromethane DMF DMF DMF DMF Methanol DMF Nitromethane

0.05 0 76

n-ButylO.72 0 0

0.70

0 0

0.47

0.38 0.13 0.17 0.15

n-ButylO.75 Benzyl 0.70 n-ButylO.62 nCetylO.08

a Dimethylformamide.

1.01

Wave Length

I

I

I

I

I

I

I

I

Time

(mu)

Figure 1. Reaction of RP81 with octylamine at 25'. [RPSI] = lo-) equiv l.-', (octylamine] = 2.5 X lo-) M, in 2.5% EtOH-H20. Curve 1, 1 sec; curve 2, 10 sec; curve 3 , 30 sec; curve 4, 100 sec.

I

Figure 2. Reaction of RP81 with tryptamine at 25'. [RPSl] = 2.5 X equiv I.-], pH 10.3, at 5 7 0 nm. [Tryptamine] = 2.5 X lo-) M , in 2.5% EtOH-H20. Curve 1 , 160 msec/div; curve 2, 8 msec/div; curve 3, 4 msec/div; curve 4, 1.6 msec/div.

mamide. T h e solution became reddish blue after 1 hr a n d turned t o d a r k blue after 3 hr under the experimental condiT h e elementary analyses were also carried out. tions employed. I obtained by the quaternization was soluReaction of Polycations (I) with Amines or Amino Acids. ble in methanol, ethanol, dimethylformamide, and other In Figure 1, the absorption changes a r e shown for the reacpolar solvents, but insoluble in water. Water-soluble polytions of a polycation, R P 8 1 , with n-octylamine (in 2.5% cation was easily obtained by partial quaternization of poIy(4E t O H - H 2 0 ) , which were obtained by the rapid-scan stopped-flow technique. T h e absorption peak a t A,, 570 vinylpyridine) with alkyl or benzyl halide before the quaternization with 2,4-dinitrochlorobenzene. n m appeared within 1 sec and then gradually disappeared. On the other hand, the absorption peak a t 360 n m d u e to T h e preparative procedures of a polycation (code R P - 2 ) 2,4-dinitroaniline increased monotonically. T h e time depenwere as follows. Benzyl chloride (14.1 ml) was added dropdence of the absorption a t 570 n m for the reaction of R P 8 1 wise into a solution of poly(4-vinylpyridine) (16.2 g ) in 300 with tryptamine is shown in Figure 2, where a rapid inml of nitromethane. T h e solution was kept a t 45O for 3 crease in the absorbance (relaxation time, Tfast = 25.6 days. T h e solvent a n d unreacted benzyl chloride were then msec) followed by a comparatively slow decrease ( T ~ =I ~ ~ eliminated by heating in vacuo. T h e residue was dissolvcd 1 1.5 sec) was observed.22 T h e overall reaction mechanism into water a n d then precipitated in dioxane. T h e dried product was hygroscopic, slightly yellow powder, 18 g yield. T h e of the polycation I with amine is believed to be given by Scheme I, by analogy with the monomeric chloride [ N degree of quaternization determined from the chloride ion (2,4-dinitrophenyl)pyridinium chloride] with amine.l7,lg analysis was 70%. T h e poly(4-vinylpyridine) partially quaT h e rate-determining steps of the formation of the colored ternized with benzyl chloride was dissolved into 100 ml of intermediate (Ic) a n d the N-substituted poly(viny1pyridiethanol. T h e solution was mixed with a n ethanolic solution nium) salt (11) a r e also believed to be that from I, to I b a n d (50 ml) of 2,4-dinitrochlorobenzeneand kept a t 35O for 2 hr, the reaction mixture turning a reddish color. T h e t h a t from I d to 11, respectively, by analogy with N-(2,4-disolution was then poured into a large quantity of dioxane. nitropheny1)pyridinium chloride with amine.l7.l8 T h e firstorder rate constants of the both steps (T-Ifast a n d T - ' ~ I ~ ~ , Decantation was twice carried out with dioxane. T h e dried respectively) are compiled in T a b l e 11. T h e reactions were product was slightly yellow powder, 13.5 g yield and 28% degree of quaternization with 2,4-dinitrochlorobenzene. carried out in water or in 2.5% ethanol-water. Anal. Calcd for (C~H~N)~.O ~H ~ (I C oN I ~ O ~ C I ) O . ~ T~h-e T-Ifast was slightly dependent on p H . I n the case of (Ci4H14NC1)0.70: C, 65.12; H, 5.09; N , 8.73; C1, 13.90. the N- (2,4-dinitrophenyl)pyridinium chloride reaction, the Found: C , 65.5; H, 5.2; N , 8.6; C1, 13.9. 7 - l f a s t depended very strongly on p H . Therefore, though the In T a b l e I, other typical polycations synthesized in the T-'fast values for t h e polymer and for N-(2,4-dinitrophenpresent paper a r e listed. Halide ion analyses were conducty1)pyridinium ion were comparable a t high p H , the former ed after each quaternization with dinitrochlorobenzene a n d became much faster t h a n the latter a t lower p H . This c a n alkyl halide t o determine the composition of the polymers. be interpreted in terms of the electrostatic attractive forces

Ise et al.

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Syntheses of Novel Catalytic Polyelectrolytes

2884 Table 11. The T-'fnst and ~

-

'

Values ~ l of ~ Reactions ~ of RP81 with Amines and Amino Acids at 25'a Concentration of amine or amino acid

Amine or amino acid

Ethylamine 2.5 Monoethanolamine 2.5 Diethy lamine 2.5 Hexylamineb 5.0 Octylamineb 5.0 Phenethylamine 2.5 Benzylamine 2.5 Aniline 2.5 Tryptamineb 2.5 2.5 p- Alanine 2.5 *Alanine a [RP81] = lo-' equiv 1.-' in H,O. b1n 2.5% ethanol-water.

'

Scheme I -CHZ-CH-

N+

sec-'

T-'fast,

x lo2, sec-'

7-lslOw

50 39

7.4 5.3

50

83 8.1 100 8.7 37 5.3 31 4.1 Very slow and faint 39 8.7 40 7.2 38 7.1

10.6

11.2 11.2

Scheme I1

-

-CH,-CH

e RNH,

QQ Q

Y'"H

NO,

I -CHz -CH

PH 10.7 9.8 10.4 10.9 11.3 10.9 10.0 8.4

OH*

I

NO, 1,

-

-CH2

NO?

histamine

-CH -

I

(RP81)

I

n-cetylamine

3

qNo2 qNoz NO,

NO,

1,

I,, colored -CH,-CH-

-CH,-CH0.172

R Id, colored

R

I1 between t h e highly charged polycation a n d the OH- ion in t h e first reaction step. T h e rate of the fading reaction (7-1slow) measured a t 570 n m of the R P 8 1 varied with amines or amino acids, which indicated that the ring-closure reaction rate (Id 11) was strongly influenced by the nucleophilicity a n d electron-donating strength of amine, etc. T h e features of 7-lslow of t h e polycation seem to be similar to those of 2,4-dinitrophenyl3-carbamoylpyridinium cation.23 It should be noted that t h e reaction (I 11) proceeded in various kinds of polar solvents, for example, water, ethanol, a n d dimethylformamide. Esterolytic Activity of the Catalytic Polyelectrolytes. T h e catalytic polyelectrolytes (I1 in Scheme I) were synthesized easily by addition of amines to I. T h e preparative procedures of S Z 8 1 1, for example, were as follows (see S c h e m e 11); a n alcoholic solution of histamine a n d then a n alcoholic solution of n-cetylamine were added t o a n alcoholic solution of RP81. After 24 hr, the solution was poured into a large excess of dioxane. T h e precipitate t h u s obtained was dried in vacuo. T h e residue was dissolved in water and treated with activated charcoal powder. T h e filtrate was then di-

-

-

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0.75

0.028 (SZ811)

H 0.05

alyzed against distilled water. T h e final polymer thus obtained contained 5% histidyl, 2.8% n-cetyl, a n d 75% n-butyl groups. Elementary analyses were carried out after the substitution with the amine, from which the composition of the product polymers was determined. T h e hydrolyses of P N P A , N A B A , and P N P P R were carried out in the presence of S Z 8 1 1. T h e saturation kinetics were observed for the three esters. T h e values of K , a n d k3 obtained from the Lineweaver-Burk plots24 a r e listed in T a b l e 111. S Z 8 1 1 having n-cetyl group is considered t o be very hydrophobic. T h u s the comparatively small values were observed for K,. Next, we synthesized other catalytic polyelectrolytes, namely, SZ11-3-1, SZ11-3-3, and SZ11-3-7 from R P 1 1 - 3 a n d various amines, i.e., histamine, P-carboxyethylamine or ethanolamine, and tested their efficiency in catalyzing the hydrolyses of P N P A a t p H 8.0. T h e Michaelis-Menten and Lineweaver-Burk profiles of the hydrolyses by SZI 1-3-1 a r e shown in Figure 3. T h e values of K , and k3 a r e compiled in Table 111. T h e fractions of the quaternized groups a r e shown in the parentheses. As is apparent from the table, the k3 value of S Z l l - 3 - 3 is three times larger t h a n that of SZ11-3-1. This may indi-

M a y 14, 1975

2885 Table 111. Hydrolyses of PNPA, PNPPR, and NABA in the Presence of S Z 8 l l or SZll-3 Series Catalysts at 30", pH 8.0

Catalyst

Ester

K,,

mM k,, min-'

SZ811 (butyl 0.75; n-cetyl PNPA" 4.6 0.26 0.028; His 0.05) PNPPRb 0.74 0.015 SZ811 NABAa 2.3 0.25 SZ811 PNPAC 3.8 0.047 SZ11-3-1 (butyl 0.62; n-cetyl 0.08; His 0.15) SZ11-3-3 (butyl 0.62; n-cetyl PNPAC 7.1 0.14 0.08; -C,H,OH 0.08; His 0.07) SZll-3-7 (butyl 0.62; n-mtyl PNPAC 6.1 0.11 0.08; -C,H,COOH 0.08; His 0.07) a I n H,O, 0.1 MKCl. bIn 50% EtOH-H,O, 0.1 MKCI.cIn 10% EtOH-H,O, 0.025 M KCl.

41 \

Figure 4. Hydrolysis of PNPA with SZI 1-3-1 and Cl6BzPVP at 30'. [SZll-3-1] = 1.6 X lo-) equiv [PNPA] = 2.5 X M. [CI~BZPVP] = 2.5 X IO-'equiv ].-I, pH 8.0, in 10% EtOH-H20.

3

2

0

0

rs1x103 . .

0.5

10

i

i'

!I

I

'

I

' j

-2

3

0

15

imi x 10-3 (M-')

Figure 3. Hydrolysis of PNPA with SZI 1-3-1 at 30'. [SZI 1-3-11 = 1.6 X IO-) equiv ] , - I , [His] = 2.82 X M . pH 8.0, 0.025 M KCI, in 10% EtOH-H20.

cate a cooperative effect between imidazolyl a n d hydroxyl groups, a s first proposed by Overberger et al.25 A cooperativity between imidazolyl a n d carboxylic acid groups also seems to exist since k3 is much larger for SZ11-3-7 t h a n for SZ11-3-1. Both the nucleophilicity of imidazole a n d the conformation of the polymer chain a r e expected to be very sensitive to ionic strength, because the present polyelectrolytes a r e strongly basic. In Figure 4, the initial rates of the hydrolyses of P N P A with S Z l l - 3 - 1 a t various concentrations of added KC1 a r e shown. T h e hydrolysis rate decreased monotonically with KCI concentration, probably because of shrinkage of the polymer coil as often observed for linear polyelectrolytes, which would "bury" the imidazolyl groups into the inner part of the polymer domain. On the other hand, in the absence of catalyst, the hydrolysis rate increased with increasing KCl concentration. This is d u e to a lowering of the activities of the reactants a n d the activated complex by the salt in alkaline hydrolysis reaction between dipole ester and ionic (OH-) species.26 c 1 6 B z P v P in Figure 4 stands for a copolymer of 4-vinylN-benzylpyridinium chloride (95%) and 4-vinyl-N-cetylpyridinium bromide ( 5 % ) , which is a strong basic and hydrophobic polymer containing no nucleophilic groups. In the absence of KC1, C16BzPVP accelerated the hydrolysis rate of P N P A several times as is seen from the figure. This is d u e t o a cooperative acceleration by electrostatic interactions between the polycations a n d OH- and hydrophobic

Ise et al.

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Syntheses of Novel Catalytic Polyelectrolytes

2886 Acknowledgment. T h e stopped-flow spectrophotometer was purchased by a g r a n t administered by the Ministry of Education. References and Notes (1)Part of this work was presented at the 2nd Symposium on Bioorganic Chemistry, Kyoto, March 1974,and at the 23rd Symposium on Polymer Chemistry, Tokyo, Oct 1974. (2) E. Katchalski, G. D. Fasman, E. Simons, E. R. Blout, and W. L. Koltun, Arch. Biochem. Biophys., 88,361 (1960). (3)R. L. Letsinger and T. J. Savereide, J. Am. Chem. Soc., 84, 114 (1962). (4)C.G. Overberger. T. St. Pierre, N. Vorchheimer, and S. Yaroslavsky. J, Am. Chem. Soc., 85,3513 (1963). (5)C.G. Overberger. T. St. Pierre, N. Vorchheimer, J. Lee, and S. Yaroslavsky, J. Am. Chem. Soc., 87,296 (1965). (6) R. L. Letsinger and 1. Klaus, J. Am. Chem. Soc., 87,3380 (1965). (7)I. M. Klotz and V. M. Stryker, J. Am. Chem. Soc., 90, 2717 (1968). (6)T. Kunitake, S. Shirnada, and C. Aso, J. Am. Chem. Soc., 91, 2716 (1969). (9)C. G. Overberger and M. Morimoto, J. Am. Chem. SOC., 93, 3222 (1971). (10)T. Kunitake and S. Shinkai, J. Am. Chem. Soc., 93,4247,4256 (1971). (11)H. C. Kiefer, W. I. Congdon, I. S. Scarpa, and I. M. Klotz, Proc. Nat. Acad. Sci. U.S.A., 69,2155 (1972). (12)C. G. Overberger and R . L. Glowaky, J. Am. Chem. SOC., 95, 6014 (1973). (13)T. Shimidzu, A. Furuta, and Y. Nakamoto, Macromolecules, 7, 160 (1974). (14)I. Tabushi and H. Kuroda, Tetrahedron Left., 643 (1974).

(15)T. Zincke, Justus Liebigs Ann. Chem., 330,361 (1904). (16)W. Konig, J. Prakt. Chem., 69, 105 (1904). (17)E. V. D. Dunghen, J. Nasielski, and P. VanLaer, Bull. SOC. Chim. Belg., 66,661 (1957). (18)J. Kavaiek and V. Sterba, Collect. Czech. Chem. Commun., 38, 3506 (1973). (19)T. OkuboandN. Ise, J. Am. Chem. SOC.,95,2293(1973). (20)N. Ise and Y. Matsuda, J. Chem. Soc., Faraday Trans. 1, 69,99 (1973). (21)The readers might be interested in our previous argument [Nature (London). 242, 605 (1973):J. Am. Chem. SOC., 95,4031 (1973)]that polymers cannot be regarded as catalysts if one follows the definition of Ostwald. (22)The absorption spectra of the intermediate showed a bathochromic shifl compared with the red color appearance (Amx 470 nm) of the correspondin monomeric N-(2,4dinitrophenyl)pyridinium chloride mixed with This may be due to the charge-transfer type interactions between a glutacondialdehyde-typeintermediate (Ic)and the neighboring free pyridine ring in the polymer. (23)E. N. Marveland I. Shahidi, J. Am. Chem. Soc., 92,5641.5646(1970). (24)W. Lineweaver and D. Burk. J. Am. Chem. Soc., 58,658 (1934). (25)C. G. Overberger, J. C. Salamone, and S. Yaroslavsky. J. Am. Chem. Soc., 89,6231 (1967). (26)For a convenient review, see, E. S. Amis and J. F. Hinton, "Solvent Effects on Chemical Phenomena", Vol. 1, Academic Press, New York. N.Y., 1973. (27)T. Okubo and N. Ise, J. Org. Chem., 38,3120 (1973). (28)T. Okubo, H. Kitano, M. Tanaka, and N. Ise. submitted to J. Org. Chem. (29)In the presence of KCI, C16BzPVP was found to be a weak catalyst for the alkaline hydrolysis of PNPA, though striking acceleration effect was observed for more hydrophobic esters, p-nitrophenyl laurate. for exam-

amine^!^-'^

le.^'

Solvolyses of 2-endo- and 2-exo- Chloro-7-thiabicyclo[2.2. llheptanes' Iwao Tabushi,*za Yoshinao TarnaqzbZen-ichi Yoshida,2b and Takuji SugimotoZb Contribution from the Department of Pharmaceutical Science, Kyushu University, Katakasu, Fukuoka, 812 Japan, and the Department of Synthetic Chemistry, Kyoto University, Sakyo-ku. Kyoto, 606 Japan. Received September 13, I973

Abstract: 2-endo-Chloro-7-thiabicyclo[2.2.1] heptane ( 5 ) was prepared from the corresponding alcohols (2-ex0 and 2-endo alcohols) exclusively by common chlorination procedures. However, 2-exo-chloro-7-thiabicyclo[2.2.1] heptane ( 7 ) was only available by the selective reduction of 2-exo-chloro-7-thiabicyclo[2.2. llheptane 7,7-dioxide with LiAIH4. The kinetics of solvolyses of these two epimeric chlorides have been measured. Acetolysis of the endo chloride was observed to follow the second-order kinetics, u = k [R-CI] [AcONa]. The mechanism involving rate-determining attack of nucleophile (AcO-) to the sulfonium intermediate (11) was first observed in the acetolyses of 5, which related to the stereospecific product formation (100% endo) and the profound acceleration by a factor of at least 4.7 X lo9 compared with the exo chloro counterpart ( 7 ) . Hydrolysis of 7 , which followed the first-order kinetics, gave skeletally rearranged 3-exo-hydroxy-2-thiabicyclo[2.2.1] heptane.

A large amount of kinetic and mechanistic investigations has been performed on the solvolyses of various norbornyl derivatives ( l).3a-c T h e rate-retarding effects of a n oxygen bridge substituted in t h e place of the methylene bridge of norbornane were observed by Martin a n d Bartlett3d (2), inCH, 0 S

1

2

3

dicating that the inductive effect of oxygen a t o m overcame t h e participation by 2 p lone pair electrons on oxygen4 a n d the incipient carbonium ion was rather destabilized. T h e neighboring sulfur a t o m has long been known as a very effective participating group, more effective t h a n oxygen in 6 or remote participation.' In order to gain further insights into the sulfur participation in solvolysis, 2-exo- and 2-endo chlorides of 7-thiabicyclo[2.2.1]heptane (3) of known geometry6 were prepared a n d solvolyses of them were per-

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formed to investigate the electronic and steric effects on the neighboring sulfur participation.

Results 2-endo-Chloro-7-thianorbornane( 5 ) was prepared from 2,s-bis-endo-dichlor0-7-thianorbornane~via the series of reactions a s shown in Scheme I, involving the interesting stereospecific and practically quantitative endo chlorination of the corresponding endo alcohol (4) (overall yield of 4 from the dichloride was 73%). Partial reduction of 2,5-bisendo-dichloro-7-thianorbornane with N a B H 4 also gave endo chloride 5 together with the recovered dichloride and thianorborane, which was identical with the chloride synthesized via S c h e m e I in every respect (GLC, ir, N M R ) . 2-exo-Chloro-7-thianorbornane(7) was, on the other hand, prepared from 7-thianorbornane dioxide via cationic chlorination with S O Z C I ~and ~ , ~the successful partial reduction with lithium aluminum hydride (see Scheme I ) . E n d o alcohol 4 was successfully oxidized to 7-thianorborna-

/ May 14, 197.5